DRAFT STANDARD
ICS: 59.080.01
Published by Ethiopian Standards Agency ©ESA
ETHIOPIAN STANDARD
Guideline for dyeing of cotton fabrics in batch, semi continuous and continuous process with reactive dyes
ES 6735:2021
First edition12-03-2021
DRAFT STANDARD
ES 6735:2021
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Foreword This Ethiopian Standard has been prepared under the direction of Technical Committee for Textile-
Dyeing and finishing (TC 71) and published by the Ethiopian Standards Agency (ESA).
Acknowledgement is made for the use of information from the above publication.
©ESA
In preparing this Ethiopian Standard the draft is presented by Ethiopian Textile Industries Development Instiute (ETIDI)
DRAFT STANDARD
Guideline for Dyeing of Cotton Fabrics in Batch, Semi
Continuous and Continuous Process with Reactive Dyes
1. SCOPE: This Ethiopian standard specifies the guideline for dyeing of cotton fabrics in batch, semi continuous and
continuous process with reactive dyes. This standard does not specify dyeing cotton with vat dyes, sulphur
dyes, direct dyes, azoic dyes and indigo dyes.
2. NORMATIVE REFERENCE The following referenced documents are indispensable for the application of this document. For dated
references, only the edition cited applies. For undated references, the latest edition of the referenced
document (including any amendments) applies.
ES 6265: Terminology Relating to Textiles
ES 6702: Sustainable textile production
ES 6736 Cleaner production for Textile Industries.
ES 6583 Code of practice for grading of textile fabrics
3. TERMS AND DEFINITION For the purpose of this standard the following definitions shall apply:- 3.1. Dyeing A method for colouring a textile material in which a dye is applied to the substrate in a uniform manner to obtain an even shade with a performance and fastness appropriate to its final use. 3.2. Dyestuff A molecule which contains a chromophoric group capable of interacting with light, thus giving the impression of colour.
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3.3. Reactive Dyes They are anionic in nature, water soluble they have better substantivity. They form strong covalent bond with cellulosic fibers. The main feature of the dyestuff is its low affinity to cellulose; therefore large amounts of salt are required to force its deposition on the fabric. They have better wash and light fastness. Alkaline condition must be required for dyeing. 3.4. Substantivity Tendency of a dye to move from a solution out of fibres in the dye solution. It is a quality of dye. Without substantivity, most of dyes would simply remain in solution or dispersion in the bath. 3.5. Exhaustion The process of transfer of dyestuff from the dye bath on to the fibre or material is known as exhaustion. 3.6. Fixation Formation of the “final” bond between the dye and the fibre with the mechanisms such as ionic bonding and hydrophobic forces. 3.7. Compatibility A state in which two things are able to exist or occur together without problems or conflict. Normally a combination of several dyestuffs is necessary to obtain a given colour. The behavior of dyes in admixture is therefore of great practical interest. Level and repeatable dyeings are achieved more easily if dyes of almost equal behavior in admixture can be selected. 3.8. Depth of shade It is a ratio of weight of dye to weight of goods dyed, usually expressed as percentage; amount of dye, owf (over the weight of fabric) 3.9. Color fastness The resistance ability of dye molecule to any agency named as washing, light, rubbing and crocking. 3.10. Level Dyeing Uniform in shade over the surface of a piece of dyed fabric or along the length of dyed yarn Level dyeing is usually the objective in commercial processes. 3.11. Padding This is the most important component of semi or continuous dyeing machines. It is a dyeing method with very low liquor to goods ratio, where typically only enough strong dye solution is used to saturate the fabric to fix the dye quickly. 3.12. Pick up% It is a ratio of amount pick or uptake by fabric when it passes through the solution or dye liquor.
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3.13. Liquor Ratio It is the ratio of the weight of the dye bath or other processing bath to the weight of the goods being dyed or processed for immersion dyeing in art dyeing processes, common liquor to goods ratio is 20:1. That is, for each kilogram of fibre to be dyed, 20 kilograms of dye bath is used of the dye solution is to be absorbed by the fibre, such as padding. 3.14. Tailing Tailing is refers to a phenomenon in which depth & shade occur on dyed fabric owing to worst distribution of dyes from top to bottom (first meters and last meters). This is a problem of semi & continuous dyeing. 3.15. Listing Listing refers to a phenomenon in which variations in depth & shade occur on dyed fabric owing to uneven dye uptake from side to side and side to center. For preventing listing during padding, padding liquor should be taken up uniformly onto textile substrate from side to center, while the textile substrate are immersed in padding liquor for a very short time & then squeezed. 4. GENERAL PRECAUTIONS TO OBTAIN LEVEL DYEING WITH CONSISTENCY
4.1. Ready for dyeing (RFD) fabric 4.1.1. Prior to preparation, greige goods should be thoroughly inspected as ES 6583
4.1.2. Fabric should have uniform absorbency and whiteness throughout the length and across.
4.1.3. Residual size must always be removed from woven goods because of the risk of dye wastage
by reaction with hydroxyl groups in size components.
4.1.4. The fabrics should be free from alkali and should be in neutral condition
4.1.5. Proper neutralization of core alkali prior to drying is essential to avoid shade change and
hydrolysis of dye-fibre bond.
4.1.6. Where bleaching is necessary, the bleached fabric should be free from traces of residual
chlorine or peroxy compounds.
4.1.7. There is considerable variation in the ability of reactive dyes to cover dead or immature cotton.
For this reason it should be to causticize or mercerize woven fabrics in order to achieve a
satisfactory appearance in certain hues.
4.1.8. The fabric should also be free from earth metals & salts (Fe, Ca, Mg)
4.1.9. The woven fabric pieces should be sown together tail-to-head, forming a sort of “ribbon”. Fabric
stitching should not be overlapped.
4.1.10. The seam must be as flat as possible to avoid forming an impression on the fabric layers.
4.1.11. Over drying, or drying too quickly at too high a temperature, may decrease dye penetration.
Fabric should be cooled before rolling or plaiting.
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4.1.12. Before padding the woven fabric should be properly conditioned and cooled so that moisture
content and temperature of fabric is same throughout the batch.
4.1.13. It is essential that all the fabrics in the roll should be of the same width.
4.1.14. The fabric should be on roller with coincident selvedges, i. e, no part of selvedges should
come out of the roll, as that portion will be dyed differently
4.2. Handling of reactive dyes 4.2.1. Because most reactive dyes are prone to hydrolysis, their handling and use should be with
care.
4.2.2. Most are readily water-soluble and the dye solution should be prepared in the usual way by
pasting with water and then adding more water.
4.2.3. Hot water should not be used for dissolving dyes of high reactivity, because of the risk of
hydrolysis of the reactive group, but is suitable for the less reactive types.
4.2.4. Once the dye solution has been prepared, it should not be stored for later use without some
risk of hydrolysis of the reactive group.
4.2.5. Vinyl sulphone (Dyes containing a 2-sulphatoethylsulphone group) however, can be dissolved
in neutral water at the boil without risk of hydrolysis.
4.2.6. Reactive dyes from different manufacturers’ ranges should not be used in the same recipe,
unless it is known that they contain the same reactive system.
4.2.7. Dyestuffs used in combination should be compatible and have similar exhaustion and fixation
profile.
4.2.8. Dyes should have good solubility in presence of salt and alkali at given dyeing temperature.
Use of leveling agent, dye bath conditioner, solubilizing agent is recommended as preventive
measure.
4.2.9. Pre-dissolved and filtered dyestuff solution is dosed linearly in the dyeing machine.
4.2.10. Liquor ratio for dyeing is adjusted in such a way that after adding dyestuff solution, salt
solution and alkali solution, it is maintained at required ratio.
4.3. Selection of reactive dyes 4.3.1. The guiding principle governing dye selection should be to obtain the desired hue and colour
fastness by an economical process that results in a good-quality dyed fabric.
4.3.2. Method of dyeing used should be as per recommendations by dyestuff supplier i.e. whether salt
in beginning, dyestuff in beginning or all in one or isothermal dyeing method. For comparison
of application properties of reactive dyes see the table 1 below:-
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Table 1: comparison of application properties of reactive dyes Property
Dyes
Substantivity Dyeing
T0C
Fixation
%
Wash ability
Stability to alkali
Stability to acid
Dyeing method
Batch Continuous Cold pad
batch
VS Low 50-60 60-70 Good Bad Good Good Good Good
Supra Medium 60-70 80-90 Good Good Good Good Good Good
MCT High 80 70-80 Bad Good Medium Good Good Bad
VS--Vinyl sulphone
SUPRA Hetro bifunctional that carry monochlorotriazine and sulphato ethyl sulphone reactive
systems
MCT-- Monochlorotriazines
Factors affecting dyeing properties of reactive dyes: type and number of reactive group,
chemical structure of chromogens, bridging group
Factors affecting substantivity in reactive dyeing: Chemical structure of reactive dye,
concentration of dye, liquor ratio, amount of neutral salt, dyeing temperature, rate of heating,
pH, etc.
4.4. Dyeing process of reactive dyes 4.4.1. Dyeing process of reactive dyes for MCT (Monochlorotriazines), VS (Vinyl sulphone) and
Supra (Hetro bifunctional that carry monochlorotriazine and sulphato ethyl sulphone reactive
systems) should be as in the diagram shown below:-
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Diagram: Dyeing process of reactive dyes
4.5. Fastness properties of reactive dyes on cotton
4.5.1. The washing procedure should remove completely the unfixed and hydrolyzed dye. Apparent
inferior fastness to washing is usually because of incomplete removal of unreacted and
hydrolyzed dye from the material by washing after dyeing.
4.5.2. In particular, the fastness to bleaching by chlorine, and to a lesser extent by peroxides present
in modern household detergents, is often only moderate. Therefore, care should be taken.
4.5.3. Any shade change due to dye fixing or finishing should be taken into account while finalizing
the recipe of lab dips or submitting shade for approval.
4.6. Water quality for the dye house 4.6.1. Although seldom sensitive to neutral hard water, precipitation of hardness constituents results
at the alkaline fixation stage and thus soft water should be used for all dissolving and dye bath
operations. (Annex B)
4.6.2. Typical dye house water quality shoiuld be as tale 2 below
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Table 2: Typical dye house water quality Component Values pH value 7.0–7.5
Total hardness (ppm, CaCO3 10–25
Iron ((ppm) 0.02–0.1 Manganese (ppm) 0.03 Alkalinity to Methyl Orange
(ppm, CaCO3)
35–65
Dissolved solids Total dissolved solids (ppm) 65–150 Suspended solids (ppm) Nil
Chloride (ppm) 0–30
Sulphate (ppm) 0–30
5. BATCH DYEING PRINCIPLES, STANDARD OPERARING PROCEDURE AND PROCESS CONTROL
5.1. General principle of batch dyeing A typical exhaust dyeing process for cellulosic materials using reactive dyes should follow the
following three phases:
a) The initial exhaustion phase
b) The fixation phase
c) The post-dyeing washing.
5.2. Standard operating procedure of batch dyeing 5.2.1. Dyeing of knitted fabric dyeing in winch dyeing machine
Knitted fabric dyeing by exhaust process in winch dyeing machines for hot brand reactive dyes
should be as follows:-
(For bleached mercerized cotton using reactive dyes, liquor ratio 20:1, 3% C.I. Reactive dye 3%)
• Set the bath at room temperature-250C
• Add the prepared dye solution
• Raise the temperature to 490C and hold for 40 minute
• Add salt 100 gram/litre in four portions over 40 minute while raising the temperature to 800C
• Dye at 800C for 20 minute
• Then add 20 gram/litre soda ash and 1 gram/litre caustic soda
• Run at 800C for 50 minute
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• Drop bath
• Check the shade and adjust, if necessary
• Cold rinse 10 minute
• Drop bath
• Hot rinse at 650C 10 minute
• Drop bath
• Set soaping bath at 380C with 1 gram/litre anionic surfactant and 1 gram/litre soda ash, Run
for 15 minute at 1000C
• Cool to 700C
• Drop bath
• Give hot rinse 650C 10 minute
• Give cold rinse 10 minute
• Drop bath and finish
5.3 Salt and alkali for hot brand reactive dyes should be as in the table 3 below:-
Salt and alkali concentration Shade %
Common salt or Glauber’s salt (g/l)
Soda ash (g/l) NaOH (g/l)
Below 0.5% 30 20 2
0.5% - 2.0% 45 20 2
2.0% - 4.0% 70 20 2
4.0% & Above 90 20 2
For shade adjustment, if dye addition is above 25% of the original recipe, a fresh bath should be set.
If dye addition is below 25% of the original recipe half bath method or full bath method should be
used.
Half bath shading a) Drop half of the bath and add cold water to reduce temperature and electrolyte
concentration.
b) Add well diluted pre-dissolved dye and dye for 10 minute.
c) Raise the temperature to 800C and dye for 30 minute 800C.
d) Check the shade.
The full bath is applicable when faster cooling is possible. The method is a) Cool dye bath to 600C
b) Add well diluted pre-dissolved dye and dye for 10 minute
c) Raise the temperature to 800C and dye for 30 minute at 800C
d) Check the shade
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5.2.2. Dyeing of woven fabrics in jigger dyeing machine (for cold brand reactive dyes)
5.2.2.1. Cold brand dyes preferred for heavy dark shades (DCT)
5.2.2.2. Dye is pasted with Turkey Red Oil followed by dissolution in water and with little urea
5.2.2.3. Fabric to be dyed is wetted in bath or loaded in jigger
5.2.2.4. Exhaustion is carried with only addition of dye for 30 minute with half dye solution in first
turn and rest half in the second turn at 300C
5.2.2.5. Then Sodium chloride is added 30-50gram/liter and dyeing continued till temperature 40-
450C, for 1-2 hour
5.2.2.6. 5-10 gram/litre Soda ash--Na2CO3 added and fixation will continue for 45 min
5.2.2.7. Drop bath
5.2.2.8. Check the shade and adjust, if necessary
5.2.2.9. Cold rinse 10 minute
5.2.2.10. Drop bath
5.2.2.11. Hot rinse at 650C 10 minute
5.2.2.12. Drop bath
5.2.2.13. Set soaping bath at 380C with 1 gram/litre anionic surfactant and 1 gram/litre soda ash,
Run for 15 minute at 1000C
5.2.2.14. Cool to 700C
5.2.2.15. Drop bath
5.2.2.16. Give hot rinse 650C 10 minute
5.2.2.17. Give cold rinse 10 minute
5.2.2.18. Drop bath and finish
Salt and alkali for cold brand reactive dyes should be as in the table 4 below:-
Shade % COMMON salt (g/l)
Soda ash at M : L Ratio (g/l)
1:15 1:20 Jigger
Below 0.5% 25 5 3 5
0.5% - 2.0% 35 5 4 10
2.0% - 4.0% 45 10 8 15
4.0% & Above 55 15 10 20
5.2.3. Dyeing of woven fabrics with Remazol dyes or Mixed Bifunctional (ME) in jigger in (all-in
method)
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5.2.3.1. Dyeing is started at 40-450C with a half dye solution, along with half slat and half alkali for
the first turn
5.2.3.2. Followed by rest half of dye, salt and alkali in the second turn
5.2.3.3. Dyeing is continued for 1 hour and temp raised to 800C
5.2.3.4. After which 45 min is further followed for fixation
5.2.3.5. Check the shade and adjust, if necessary
5.2.3.6. Washing and soaping as usual.
Salt and alkali for vinyl sulphone and Mixed Bifunctional (ME) type reactive dyes should be as in the
table 5 below:-
Shade % Glauber’s salt (g/l) Soda ash (g/l)
0.05% 3-5 10-15
0.05% - 0.1% 3-8 10-15
0.1% - 0.5% 15-25 10-20
0.5% - 1.0% 25-35 20
1.0% - 2.0% 40-50 20
>2.0% 50 20
5.3. Process control in batch dyeing 5.3.1. Winch dyeing
5.3.1.1. Temperature of dyeing: Generally for clod brand dye—30-400C and for hot brand dyes 60-
800C.
5.3.1.2. Dye bath pH: For cold brand reactive dyes(high reactive dyes) , milder pH -- pH 8.8-10.0 is
used , For hot brand reactive dyes stronger PH-- pH 10.5 to 11.0 is used
5.3.1.3. Time of dyeing: Exhaustion time is 20-30 minute is used. Increase beyond this has no
effect on exhaustion. For fixation 30- 60in used depending on the depth of shade
5.3.1.4. Endless ropes or loops of fabrics to be loaded should be equal length (about 50-100m).
5.3.1.5. As for all forms of rope dyeing, the fabric should be fairly resistant to length ways creasing.
5.3.1.6. The maximum motion speed of the fabric should be approximately 40m/min
5.3.2. Jigger dyeing 5.3.2.1. Batching: Knife cut batching (very even batching). If batching is not even, then segregate
the fabric or dry the fabric on the stenter. During batching another precaution is that the
expanders of the jigger must work properly.
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5.3.2.2. MLR: Jigger dyeing machine is 1:1 to 1:1.5. During colouration 1:1.5, during soaping 1:2,
during soaping for overflow washing it is 1:5. Maintain constant water level for over flow
washing.
5.3.2.3. Prevent water and steam leakages.
5.3.2.4. Crease free fabric: Creases are found near the selvedges. So it has to be removed
immediately. Creases are formed in between the fabric due to the improper working of
expanders.
5.3.2.5. Colour and Chemical Addition: Importantly colour and chemically addition should be in
even installments and not in odd installments.
5.3.2.6. Proper stirring of the solution in the trough after every addition. All solid chemicals must be
added by pre-dissolving.
5.3.2.7. Temperature: During dyeing with the help of the thermometer check the temperature and
the standard of temperature should be as per the class of the dye.
5.3.2.8. pH: Check pH during dyeing as per the class of the dye. Give optimum dose of alkali and
acids in the trough.
5.3.2.9. Addition of colours for the correction of the shade
5.3.2.10. Speed should optimum and constant (avoid speed ab0ve 80metee/min)
5.3.2.11. Ensure that addition must be done in the jigger by draining half quantity of trough solution.
The reason is that the new dye requirement to set the shade right will be less as the dye
initially present has reduced to half the quantity plus in addition there will be shift in
equilibrium and hence dyeing will again start and lead to shade correction.
6. SEMI COTNIUOUS DYEING PRINCIPLES, STANDARD OPERARING PROCEDURE AND PROCESS CONTROL
6.1. Standard operating procedure for cold pad batch 6.1.1. All pad–batch processes should follow the following general sequence:
a) Impregnation of the well-prepared dry fabric in a solution of dye and alkali at ambient
temperature.
b) Uniform squeezing of surplus liquor from the fabric as it passes through the mangle nip.
c) Wrapping of the batched roll of wet fabric in polythene film and storage at ambient
temperature for a specified dwell time (2–24 h, depending on dye reactivity and pH).
d) Washing-off of unfixed dye.
e) Drying of the washed dyeing.
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6.1.2. This should be used for dyeing of dark shade.
6.1.3. For pad-batch dyeing, reactive dyes with relatively high reactivity should be used. Some
examples are Dichlorotriazine, Monofluorotriazine, Dichloroquinoxaline, Vinyl sulfones and
selected Bi-reactive dyes.
6.1.4. Auxiliary chemicals in the pad-batch dye liquor should include alkalis, urea, and wetting agents.
6.1.5. A wetting agent or surfactant which is low foaming and which provides rapid wetting and
penetration of dye into the cotton fiber should be added to the dye liquor.
6.1.6. The recipe for cold pad batch should be based on the table below:
Table 6: Sample cotton reactive dyeing recipe on cod pad batch
PH: 11
Temperature: RT (padding & dwelling)
Speed: 6-60m/min (depends on the fabric weight) ( for canvas 25m/min, light weight fabrics 50m/min)
Batch dwelling time: 8-24hr (varies with reactivity of dyestuff used)
DPF (dye pick up factor):-average 70%
Inputs (dyes/ chemicals/ auxiliaries) Deep shade Medium shade Light shade
Dye solution
Reactive dye [% On weight of fabric] x y z
Urea [g per L of solution] 50 30-50 20-30
Sequestering agent [ml per L of solution] 2 2 2
Wetting agent [g per L of solution] 2-4 2-4 2-4
Alkali solution
Caustic soda [ml per L of solution] 8 4 0.6
Soda ash [g per L of solution] 20-30 20-30 20-30
Ratio of application (Alkali: Dyestuff soln.) 1:4 1:4 1:4
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6.2. Process control cold pad batch dyeing 6.2.1. When preparing the pad-batch dye bath, the dyestuff and alkali should first be prepared in
separate tanks as separate solutions.
6.2.2. Automatic mixing of the dyestuff and alkali solutions should be a ratio of 4 to 1. This mix feeds
into a small, 5 gallon (19 liter) holding tank for uniform blending prior to transfer to the pad
trough.
6.2.3. The dyestuff solution should be prepared by dissolving the dyestuff completely in water at the
temperature recommended by the dyestuff supplier.
6.2.4. To avoid evaporation from the exposed surfaces and edges of the roll, the fabric is stitched to a
somewhat wider end-cloth that is padded and finally wrapped around the entire wet roll before it
is covered with a plastic film
6.2.5. The required alkali solution should be prepared in a separate tank and the temperature kept
close to the padding conditions.
6.2.6. Metering pumps made by several companies (listed under suppliers) should be used to provide
adequate and reproducible mixing of pad-batch dye baths over extended periods of use.
6.2.7. Final bath temperature after mixing should be kept between 18-300C to ensure consistency
and reproducibility.
6.2.8. Before padding the dye solution onto the fabric the following should be checked:-
a) Fabric style and accurate weight of dye lot.
b) All dispensing lines must be clean.
c) Pad trough must be rinsed out well.
d) Check function of mixing pump blending ratio of alkali and fiber-reactive dye.
e) Check pad pressure side to side and center.
f) Check wet pickup.
g) Calculate volume of formula based on wet pickup to have sufficient dye liquor for the entire
lot.
h) Check all functions on operating panel.
6.2.9. Although high-reactivity dyes may be preferred because they enable dwell times as short as 2–
4 h to be used, demands for specific hues, fastness or cost advantages may favour applying
low-reactivity dyes at high pH for longer dwell times, possibly 16–24 h or longer
6.2.10. Dyes having similar affinities should be used to avoid tailing.
6.2.11. Running conditions that allow a complete change of liquor in the trough every 2–3 min
throughout the run are ideal for most purposes.
6.2.12. Padding should be done at uniform wet pick-up across the width.
6.2.13. Mangle pressures are set to give a liquor pick-up of 60–80% at ambient temperature.
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6.2.14. In pad–batch dyeing with Remazol dyes, the buffering action of sodium meta-silicate added
to the NaOH solution is claimed to virtually eliminate the problem of paler selvages from
carbon dioxide absorption.
7. CONTINUOUS DYEING PRINCIPLES, STANDARD OPERARING PROCEDURE AND PROCESS CONTROL
7.1. General principles of continuous dyeing 7.1.1. The objective of padding should be to impregnate the fabric with a solution or dispersion of
dyes and chemicals as uniformly as possibly, both lengthways and side-to-side.
7.1.2. To produce long lengths of fabric, all with the same colour, requires the maintenance of
constant padding conditions over long periods of time
7.1.3. The fabric should first passes through the pad trough, where it is saturated with dye solution,
and then between the rollers, where the pressure squeezes air out of the fabric and the solution
into it.
7.1.4. Continuous dyeing processes should follow these four stages:-
i. Dye application by padding;
ii. Dye fixation, usually in hot air or steam;
iii. Washing-off of unfixed dye and auxiliary chemicals;
iv. Drying, usually on steam-heated cylinders.
7.2. Standard operation procedure for dyeing of woven fabrics with continuous processes 7.2.1. Pad—steam should be:-
7.2.1.1. Recipe X g/l dye, 10-20 g/l soda ash, 1g/l of wetting agent (penetrating agent), salt 60-
90 g/l, resist salt 2g/l.
7.2.1.2. The application is padding---steaming (90 sec)—washing
7.2.1.3. The method should be used for high quality pale shades giving high rate of productivity.
7.2.1.4. High expression padding mangles should be used.
7.2.1.5. Cold brand reactive dyes should be used.
7.2.2. Pad-dry-pad (alkali)-steam (PDPS dyeing procedure should be:- 7.2.2.1. Padding( dye liquor)
• 4 gm/litre dye (Vinyl Sulphone dye)
• 50 gm/litre Urea
• 2 gm/litre Sodium Alginate
• 50 gm/litre common salt
• Pick up 60-80%
7.2.2.2. Drying • Infrared drying (after infra red drying moisture content is 30%)
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• Hot flue drying 120-130°C
• After drying, the fabric should be cooled on cold cylinders to avoid heating the chemical
pad solution.
7.2.2.3. Padding( chemical liquor) • 200-250 gm/litre common salt (Reduces the bleeding of dye from padded material to
alkaline bath)
• 15ml/litre Caustic soda 360Be
• 20 gm/litre soda ash
7.2.2.4. Steaming • 30-60 second with saturated steam
7.2.2.5. Washing off • Through washing
7.2.3. Pad (Dye + bicarbonate+ urea) - dry should be: 7.2.3.1. This should be used valuable process for cheap and easy production of pale and
medium depth of shade. ( Realization of colour is poor)
7.2.3.2. This should be used valuable process for cheap and easy production of pale and
medium depth of shade. ( Realization of colour is poor)
7.2.3.3. Should use slow and even drying in hot flue drier to avoid migration and uneven dyeing.
7.2.3.4. Sodium bicarbonate should be used as a fixation alkali and hot flue dryer with free
moisture are two important parameters for better fixation.
7.2.3.5. Minimum moisture for this process is around 20%.
7.2.3.6. The dye solution also contains a high concentration of urea (100 g l–1). This helps the
cotton fibres retain water during drying, possibly provides a fluid medium for dye
diffusion in the fibres at low water contents, and increases dye solubility.
7.2.3.7. The pad–dry process is only suitable for reactive dyes with fairly high reactivity. For dyes
of lower reactivity, the dried fabric must be baked to promote further fixation.
7.2.4. Pad (Dye + bicarbonate+ urea) – dry-bake should be: 7.2.4.1. The pad–dry–bake process is suitable for less reactive dyes such as MCT
(Monochlorotriazines) dyes.
7.2.4.2. Typically for pad –dry-bake, the dyes are padded with
• 10–20 g l–1 sodium bi carbonate and
• 100–200 g l–1 urea.
7.2.4.3. Little fixation takes place during intermediate drying (Typical conditions are 2–5 minute
at 105 °C in a hot flue or on heated cylinders at 105 °C. The fabric temperature will not
exceed 70 °C)
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7.2.4.4. And a baking treatment (e.g. 3 minute at 160°C) is necessary to complete the dye–fibre
reaction.
7.3. Process control in continuous dyeing 7.3.1. General issues
7.3.1.1. Marks on the padded fabric from un-dissolved dye particles or un-dispersed pigment, or
those arising from foam picked up from the surface of the dye liquor in the pad, which is
squeezed onto the fabric surface should be avoided.
7.3.1.2. Suitable wetting and deaerating agent, low foaming type should be used for uniform
padding and rapid wetting with dyestuff solution.
7.3.1.3. Suitable anti-migrating agent should be used to avoid variation due to migration during
intermediate drying.
7.3.1.4. Dyestuff used for padding should be of medium to low affinity to avoid tailing.
7.3.1.5. Padding trough should be jacketed and be maintained at required temperature by
circulating cold water to avoid increase in temperature during padding due to heat
entrapped in fabric, batched in roll form after drying on cylinder.
7.3.1.6. All contact points must be cleaned during change over to avoid contamination.
7.3.2. Fabric-in-feed 7.3.2.1. The fabric should be free of creases and have flat selvages. It is accurately centered on
the rollers and runs under moderate tension.
7.3.2.2. Open width fabric should be processed under uniform tension, before entering the
padder and during take-up on the beam.
7.3.2.3. Speed and temperature control should be there.
7.3.2.4. Synchronized fabric guidance - in feed / take up should be used.
7.3.3. Nip rolls 7.3.3.1. Nip rolls should be clean
7.3.3.2. The covering of both bowls should be of uniform hardness to prevent two sided
problems
7.3.3.3. Damage to the nip rolls should be maintained to avoid poor appearance of the dyed
fabric and pick-up variations.
7.3.4. Trough content 7.3.4.1. The volume in the pad trough should be relatively small (20 – 50 litres) and
automatically controlled at a constant level throughout the run.( Pad bath level variations
result in a shade differences caused by variations in immersion time & pick up
7.3.4.2. The pad liquor turnover time should be as fast as possible
7.3.4.3. The pad liquor should be distributed uniformly across the full width of the padder through
a perforated tube
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7.3.5. Pick up 7.3.5.1. Should be uniform across the width and consistent from batch to batch (60 – 80% for
cotton fabrics)
7.3.5.2. Factors which Pick-up depends upon should be controlled.--Pad pressure and speed
(fabric penetration, wetting out), dye level in the trough (dip to nip time), dye bath
chemicals (penetration accelerant), fabric (fibre and construction).
7.3.6. Immersion time 7.3.6.1. Should be 1 – 2 s for cotton
7.3.7. Speed 7.3.7.1. should be constant throughout the run - No stoppages
7.3.8. Padding temperature 7.3.8.1. Pad bath temperature is critical and should be within the specification.
7.3.9. Migration 7.3.9.1. To control dye migration, the following factors should be kept— Lower pick-up, Skying
between padding and drying, Infra-red pre-drying (most important), Well balanced air
flow in the dryer, Use of a migration inhibitor and Better dye selection Migration stops
when the moisture content of the fabric has dropped below 30%
7.3.10. Infrared pre-drying 7.3.10.1. Temperature/capacity adjusted depending upon weight of fabric, Moisture content of
fabric after pre-drying and Cleaning of guide rollers
7.3.11. Hot flue Driers 7.3.11.1. Uniform air distribution, Temperature control, Uniform fabric tension to prevent
creasing, Graduated temperature between the hot flue chambers, Drying time – no over
drying and Cooling down of fabric after drying
7.3.12. Cylinder driers should be 7.3.12.1. Sufficient steam pressure and supply should be there--Prevent condensation in the
cylinders, Cylinders should be properly aligned, well balanced and clean and Fabric
cooling after drying should be used
7.3.13. Steaming 7.3.13.1. Steam Fixation requirements should be:-
a) Maintain control for an air free atmosphere of saturated steam, Sufficient steam
pressure and supply
b) Measurement of wet & dry bulb temperatures
c) Prevention of condensation drops ( heating of steamer entrance & roof)
d) Fabric cooling before padding
e) Control chemical pad recipe and pick up
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f) Fabric tension and steaming time( 20 -60 sec)
g) A steamer typically holds about 30–60 m of fabric. Again, good roller alignment is
necessary to avoid lengthways creases.
h) The roof of the steamer should be well insulated.
i) The saturated steam in the box should be slightly superheated (105 °C).
j) Water seal
8. QUALITY CONTROL IN DYEING Through checking the shade of dyed fabrics, the fastness properties should be worked out. The quality
of dyed fabrics is assured in laboratory, dyeing section and finishing section.
8.1. In laboratory: 8.1.1. Receive swatch card from buyers according to their requirement.
8.1.2. Dye sample by manually or CCMS.
8.1.3. Dye sample until matching with swatch card.
8.1.4. Fastness & other tests of fabrics can be also carried out.
8.2. In dyeing section 8.2.1. Dye sample in dyeing machine and dyeing shed, matching with the approved sample.
8.2.2. Move to bulk production, if the result is matched with approved sample.
8.2.3. During dyeing, take the samples when accurate shade matching accurate shade.
8.2.4. Collect dyeing sample which having been softened.
8.2.5. Last of all, collect sample from fixation & matched.
8.2.6. Allow fabrics to be finished.
8.3. DYEING DEFFECTS The following dyeing defect should be checked:-
8.3.1. Shade variation
8.3.2. Batch to batch Shade consistency
8.3.3. Washing fastness, perspiration fastness, rubbing fastness, light fastness and Chlorine,
8.3.4. Dye Spots
8.3.5. Unevenness/unevenness
8.3.6. Contamination
8.3.7. White marks
8.3.8. Holes
8.3.9. Creases
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BIBLIOGRAPHY
Basic principles of Textile Coloration, Arthur Broadbent, Society of Dyers and Colorists, 2001.
Fundamentals and Practices of Colouration of Textiles, J.N.Chakraporthy, Woodhead Publication
India PVT Limited.
Cellulosic Dyeing, John Shore, Society of Dyers and Colorists, 1995. Textile preparation and Dyeing, Asim Kumar Roy Choudhury, Society of Dyers and Colourist,2011
Chemical Technology in the Coloration of Textiles, Volume 1, S.R. Karmakar, Mumbai, India.
Fibres Dyeing Manual Ethiopian Textile Industry Development Institute, Finishing Technology
Directorate, Nov 2017.
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The Head Office of ESA is at Addis Ababa.
011- 646 06 85, 011- 646 05 65 011-646 08 80 2310 Addis Ababa, Ethiopia E-mail: [email protected], Website: www.ethiostandards.org
Organization and Objectives
The Ethiopian Standards Agency (ESA) is the national standards body of Ethiopia established in 2010 based on regulation No. 193/2010.ESA is established due to the restructuring of Quality and Standards Authority o f Ethiopia ( QSAE) which was established in 1998.
ESA’s objectives are:-
Develop Ethiopian standards and establish a system that enable to check whether goods and services are in compliance with the required standards,
Facilitat the country’s technology transfer through the use of standards,
Develop national standards for local products and services so as to make them competitive in the international market.
Ethiopian Standards
The Ethiopian Standards are developed by national technical committees which are composed of different stakeholders consisting of educational institutions, research institutes, government organizations, certification, inspection, and testing organizations, regulatory bodies, consumer association etc. The requirements and/ or recommendations contained in Ethiopian Standards are consensus based that reflects the interest of the TC representatives and also of comments received from the public and other sources. Ethiopian Standards are approved by the National Standardization Council and are kept under continuous review after publication and updated regularly to take account of latest scientific and technological changes. Orders for all Ethiopian Standards, International Standard and ASTM standards, including electronic versions, should be addressed to the Documentation and Publication Team at the Head office and Branch (Liaisons) offices. A catalogue of Ethiopian Standards is also available freely and can be accessed in from our website.
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